Quad flat package

ABSTRACT

A semiconductor package includes a leadframe having first and second level downset lead extensions, a quad flat nonleaded package (QFN) attached to the first level downset lead extension, and a flip chip die attached to the second level downset lead extension. Another embodiment of a semiconductor package includes a leadframe having a lead, a first quad flat nonleaded package (QFN) connected to the lead, and a second quad flat nonleaded package invertly connected to a top surface of the first quad flat nonleaded package, wherein the second quad flat nonleaded package is wirebonded to the lead. A third embodiment of a semiconductor package includes a leadframe having a lead with a first level downset lead extension, a quad flat nonleaded package (QFN) connected to the first level downset lead extension, and a first wirebondable die attached to a top or bottom surface of the quad flat nonleaded package.

FIELD OF THE INVENTION

The present invention relates in general to semiconductor devices and,more particularly, to multi-chip semiconductor packages that havestacked dies.

BACKGROUND OF THE INVENTION

Semiconductors, or computer chips, are found in virtually everyelectrical product manufactured today. Chips are used not only in verysophisticated industrial and commercial electronic equipment, but alsoin many household and consumer items such as televisions, clotheswashers and dryers, radios, and telephones. As products become smallerbut more functional, there is a need to include more chips in thesmaller products to perform the functionality. The reduction in size ofcellular telephones is one example of how more and more capabilities areincorporated into smaller and smaller electronic products.

As the demand for semiconductor devices with low-cost, high performance,increased miniaturization, and greater packaging densities hasincreased, Multi-Chip Module (MCM) structures have been developed tomeet the demand. MCM structures have a number of dies and othersemiconductor components mounted within a single semiconductor package.The number of dies and other components can be mounted in a verticalmanner, a lateral manner, or combinations thereof.

One such approach is to stack one die on top of another and then enclosethe stack of dies in one package. The final package for a semiconductorwith stacked dies is much smaller than would result if the dies wereeach packaged separately. In addition to providing a smaller size,stacked-die packages offer a number of advantages that relate to themanufacturing of the package, such as ease of handling and assembly.

In a stacked-die arrangement, the dies are wire-bonded sequentially,typically with automated wire-bonding equipment employing well-knownthermal compression or ultrasonic wire-bonding techniques. During thewire-bonding process, the head of a wire-bonding apparatus applies adownward pressure on a conductive wire held in contact with awire-bonding pad on the die to weld, or bond, the wire to the bondingpad on the die.

In many cases, stacked-die semiconductors can be fabricated faster andmore cheaply than several semiconductors, each having a single die,which perform the same functions. A stacked-die approach is advantageousbecause of the increase in circuit density achieved.

A variety of semiconductor package configurations having stacked diearrangements are found in the art. However, the configurations fail toutilize a known quad flat nonleaded package (QFN) which is incorporatedwith a flipchip die and/or a wirebondable die into a quad flat package(QFP).

Accordingly, a need exists for a QFP utilizing a known QFN package, aflipchip die and/or a wirebondable die to provide cost efficiency, theQFP having the previously described configurability.

SUMMARY OF THE INVENTION

In one embodiment, the present invention is a semiconductor package,comprising a leadframe having first and second level downset leadextensions, a quad flat nonleaded package (QFN) attached to the firstlevel downset lead extension, and a flip chip die attached to the secondlevel downset lead extension.

In another embodiment, the present invention is a semiconductor package,comprising a leadframe having a lead, a first quad flat nonleadedpackage (QFN) connected to the lead, and a second quad flat nonleadedpackage invertly connected to a top surface of the first quad flatnonleaded package, wherein the second quad flat nonleaded package iswirebonded to the lead.

In another embodiment, the present invention is a semiconductor package,comprising a leadframe having a lead with a first level downset leadextension, a quad flat nonleaded package (QFN) connected to the firstlevel downset lead extension, and a first wirebondable die attached to atop or bottom surface of the quad flat nonleaded package.

In still another embodiment, the present invention is a method ofmanufacturing a semiconductor package, comprising providing a leadframehaving first and second level downset lead extensions, connecting a quadflat nonleaded package (QFN) to the first level downset lead extensions,and connecting a flip chip die attached to the second level downset leadextension.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 a illustrates an example embodiment of a standard quad flatpackage (QFP) having an incorporated quad flat nonleaded package (QFN)and flip chip semiconductor die;

FIG. 1 b illustrates a lead having a first level downset lead extension;

FIG. 1 c illustrates a lead having first and second level downset leadextensions;

FIG. 2 illustrates example dimensions of a quad flat package havingfirst and second downset lead extensions;

FIG. 3 a illustrates a second example embodiment of a QFP having anadditional semiconductor die attached on a top surface of the QFNpackage;

FIG. 3 b illustrates a first lead type which is compatible with theembodiment shown in FIG. 3 a;

FIG. 3 c illustrates a second lead type which is compatible with theembodiment shown in FIG. 3 a;

FIG. 3 d illustrates a third lead type which is compatible with theembodiment shown in FIG. 3 a;

FIG. 4 a illustrates a third example embodiment of a QFP having twointegrated QFN packages;

FIG. 4 b illustrates a first lead type which is compatible with theembodiment shown in FIG. 4 a;

FIG. 4 c illustrates a second lead type which is compatible with theembodiment shown in FIG. 4 b;

FIG. 5 illustrates a fourth example embodiment of a QFP having twointegrated QFN packages and an additional semiconductor die;

FIG. 6 a illustrates a fifth example embodiment of a QFP having anintegrated QFN package and a wirebonded semiconductor die attached to atop surface of the QFN package;

FIG. 6 b illustrates a sixth example embodiment of a QFP having anintegrated QFN package and a wirebonded semiconductor die attached to abottom surface of the QFN package; and

FIG. 6 c illustrates a seventh example embodiment of a QFP having anintegrated QFN package and a wirebonded semiconductor die attached to atop and bottom surface of the QFN package.

DETAILED DESCRIPTION OF THE DRAWINGS

The present invention is described in one or more embodiments in thefollowing description with reference to the Figures, in which likenumerals represent the same or similar elements. While the invention isdescribed in terms of the best mode for achieving the invention'sobjectives, it will be appreciated by those skilled in the art that itis intended to cover alternatives, modifications, and equivalents as maybe included within the spirit and scope of the invention as defined bythe appended claims and their equivalents as supported by the followingdisclosure and drawings.

A semiconductor package can be manufactured which takes into account astacked-die arrangement and serves to alleviate many of the problemspreviously described, while providing increasingly smaller sizes. Thepackage can be manufactured more easily and with greater efficiency thanprevious packages, resulting in a package with lower overallmanufacturing cost.

The semiconductor packages described below reduce incidences of upperdie cracking during wire bonding of the upper die, which providesadditional freedom in the design and location of various sized dies insemiconductor packages having stacked dies. Additionally, the packagesalleviate problems associated with heat dissipation in semiconductorpackages having multiple dies, which allows more dies to be placed in agiven semiconductor package.

The semiconductor packages described serve to reduce the amount ofadhesive material used when multiple dies are stacked, resulting in areduction in the amount of moisture that can be absorbed into thepackage. Finally, the reliability of semiconductor packages havingstacked dies is increased by use of the following designs and methods ofmanufacture.

Turning to FIG. 1 a, a first example embodiment of a semiconductorpackage 10 with a stacked-die arrangement is illustrated. Package 10consists of a standard quad flat package (QFP) 10. QFP package 10includes a leadframe 12. Connected to leadframe 12 are leads havingdownset lead extensions. A double downset lead extension structure isdepicted. A first level downset lead extension 14 is connected to asecond level downset lead extension 16. A quad flat nonleaded package(QFN) 18 is attached on the first level downset extension 14. A flipchip semiconductor die 20 is shown attached to the second level downsetextension 16. The location of die 20 and QFN 18 can be interchanged tosuit a particular application. Moreover, the QFP can include a pluralityof two or more QFN packages 18, or a plurality of any combination of QFNpackages 18 and dies 20. Package 10 can vary in size to accommodate thevarious number of subcomponent packages 18 and/or dies 20. Additionallevel downset extensions are contemplated to accommodate additionalpackages 18 and/or dies 20.

An encapsulant 22 is formed over QFN 18, die 20, and at least a portionof the first and second level downset extensions 14, 16 to providestructural support, resulting in the completed QFP 10. The manufacturingtechniques involving encapsulant 22 can include those generally known inthe art and selected for a particular application.

Downset leads 14, 16 incorporated into QFP 10 can perform a variety offunctions, including serving to control the overall stack heightpositioning inside the QFP 10, and to control the position of the QFN 18and die 20 in place, particularly during the attachment process, bylimiting the movement of QFNs 18 and dies 20.

Turning to FIG. 2, an illustration of example width dimensions of QFP 10is depicted. Again, leadframe 12, lead extensions 14, 16, QFNs 18, dies20, and encapsulant 22 are again depicted. Widths 24 and 26 are shown,which essentially constitute the gap between a vertical surface of QFN18 and/or die 20 and a vertical surface of lead extensions 14, 16. Theconfiguration of lead extensions 14, 16 allows for the minimization ofwidths 24, 26, leading to limited movement of QFN 18 and/or die 20. Thelimited movement results in increased control of positioning of QFN 18and/or die 20 along the horizontal axis during the attachment process.

QFN 18 can consist of any package variation known in the art. QFN 18 caninclude either an exposed or non-exposed wire bond pad. Example QFNpackages include flip chip quad flat nonleaded packages (fcQFN) and/orwirebonded QFNs in a single or stacked die arrangement, bump chipcarriers (BCCs), punch singulated QFNs (LFCSP), and SON packages. QFN 18can be attached using any conductive adhesive material, such as solderpaste, solder or epoxy.

The foregoing semiconductor package 10 can be fabricated by a methodcomprising the steps of: preparing a leadframe 12 having downsetextensions 14, 16, preparing a QFN package 18 and flip chipsemiconductor die 20, attaching the QFN 18 and die 20 to the extensions14, 16 to electrically interconnect the QFN 18 and die 20 to theleadframe 12, and finally, forming an encapsulant 22 to encapsulate thepackage 10 including the QFN 18, die 20 and at least a portion of thedownset extensions 14, 16 to provide structural support.

Turning to FIG. 3 a, a second example embodiment of a QFP 10 isdepicted. QFP 10 again includes leadframe 12, downset extensions 14, 16,a QFN package 18, and a flip chip die 20. Again, encapsulant 22 is shownproviding structural support. In addition to the foregoing structures,an additional wirebondable semiconductor die 28 is shown disposed on topof QFN 18. Die 28 is shown wirebonded to the QFP leads 12.

Die 28 can be attached by any adhesive material (tape or epoxy).Additionally, the adhesive material can be either a conductive ornon-conductive material. Three types of lead structures can be used inthe package 10 as depicted. FIGS. 3 b, 3 c, and 3 d depict three typesof lead structures, FIG. 3 c having a first level downset lead extension14 and FIG. 3 d having first and second level downset lead extensions14, 16. Each of the lead types depicted in FIGS. 3 b, 3 c, and 3 d canbe wirebonded to die 28.

Turning to FIG. 4 a, a third example embodiment of a package 10 isshown. Package 10 again includes a standard QFN package with twoincorporated QFN packages 18. The first, lower QFN package 18 isattached on top of the downset lead extensions 14. The second, upper QFN18 is inverted, then attached to a top surface of the first QFN 18. Thesecond, top QFN 18 is then wirebonded to the QFP leads 12. The top QFN18 can be attached by any adhesive (film or epoxy) and can consist ofconductive or non-conductive materials. FIGS. 4 b and 4 c depict twotypes of leads 12 which can be used with the depicted QFP 10 as shown inFIG. 4 a. Additionally, the types of lead structures 12 depicted inFIGS. 4 b and 4 c can be used with the embodiments depicted in FIGS. 5,6 a, 6 b and 6 c, following.

FIG. 5 depicts a fourth example embodiment of a QFP 10. QFP 10 includesan additional wirebondable semiconductor die 28 which is attached on atop surface of the inverted QFN 18. The die 28 is then wirebonded to theleads 12 with wires 32. Die 28 is also wire bonded between wire bondpads 34 on top QFN 18 and leads 12 using wires 36 as depicted. Die 28,again, can attach to top QFN 18 by any adhesive material (tape or epoxy)and either a conductive or non-conductive material.

FIG. 6 a depicts a fifth example embodiment of a QFP 10. In the depictedexample, QFP 10 includes a standard QFP package 10 having a QFN 18attached on top of the downsetted lead extensions 14. A wirebondablesemiconductor die 28 is attached on top of the QFN 18. The die 28 isthen wire bonded using wire 30 between leads 12 and wire bond pad 34 toprovide electrical connectivity. Here, as before, the first leveldownset lead extension 14 provides for limited movement of the QFNpackage 18 and/or die 28 during the attachment process for betterposition control along the horizontal axis. Additionally, the use ofextension 14 allows control over the overall stack height positioninside the QFP 10.

FIG. 6 b illustrates a sixth example embodiment of a QFP 10. Again,package 10 is a standard QFP 10 having an integrated QFN 18 packageattached on top of the downsetted lead extensions 14. A wirebondablesemiconductor die 28 is attached on the bottom of the QFN 18 package.The die 28 is then wirebonded to the leads 12 using wires 38.

FIG. 6 c illustrates a seventh example embodiment of a QFP 10. Package10 again consists of a standard QFP 10 having an integrated QFN 18package which is attached on top of the downsetted lead extensions 14.Two semiconductor dies 28 are attached on a top and a bottom surface ofQFN 18. The bottom die 28 is attached to leads 12 using wires 38. Thetop die 28 is attached to leads 12 using wires 40.

The use of package 10 as described involves new stacking conceptssuitable for a QFP package. As the cost of leaded packages is much lowerthan the costs associated with an array package, the use of package 10is less expensive, yet the needs for higher functionality and devicedensity of new generation packages are not compromised.

While one or more embodiments of the present invention have beenillustrated in detail, the skilled artisan will appreciate thatmodifications and adaptations to those embodiments may be made withoutdeparting from the scope of the present invention as set forth in thefollowing claims.

1. A semiconductor package, comprising: a leadframe having a horizontalsurface and first and second level downset lead extensions, the firstlevel downset lead extension having a vertical surface extending fromthe horizontal surface of the leadframe, the first level downset leadextension further having a horizontal surface extending from thevertical surface of the first level downset lead extension, thehorizontal surface of the first level downset lead extension beingvertically offset from the horizontal surface of the leadframe, thesecond level downset lead extension having a vertical surface extendingfrom the horizontal surface of the first level downset lead extension,the second level downset lead extension further having a horizontalsurface extending from the vertical surface of the second level downsetlead extension, the horizontal surface of the second level downset leadextension being vertically offset from the horizontal surface of thefirst level downset lead extension; a quad flat nonleaded package (QFN)attached to the horizontal surface of the first level downset leadextension with solder, the QFN being positioned within a gap of thevertical surface of the first level downset lead extension to limitmovement of the QFN during stacking; and a flip chip die attached to thehorizontal surface of the second level downset lead extension withsolder, the flip chip die being positioned within a gap of the verticalsurface of the second level downset lead extension to limit movement ofthe flip chip die during stacking.
 2. The semiconductor package of claim1, further including an encapsulant formed over the QFN for providingstructural support to the QFN within the semiconductor package.
 3. Thesemiconductor package of claim 1, further including a wirebondable dieattached to a top surface of the QFN.
 4. The semiconductor package ofclaim 3, wherein the wirebondable die is attached by an adhesivematerial.
 5. The semiconductor package of claim 4, wherein the adhesivematerial is conductive or nonconductive.
 6. A semiconductor device,comprising: a leadframe having a horizontal surface and first and secondlevel downset lead extensions, the first level downset lead extensionhaving a vertical surface extending from the horizontal surface of theleadframe, the first level downset lead extension further having ahorizontal surface extending from the vertical surface of the firstlevel downset lead extension, the horizontal surface of the first leveldownset lead extension being vertically offset from the horizontalsurface of the leadframe, the second level downset lead extension havinga vertical surface extending from the horizontal surface of the firstlevel downset lead extension, the second level downset lead extensionfurther having a horizontal surface extending from the vertical surfaceof the second level downset lead extension with solder, the horizontalsurface of the second level downset lead extension being verticallyoffset from the horizontal surface of the first level downset leadextension; a first leadless semiconductor die attached to the horizontalsurface of the first level downset lead extension with solder, the firstleadless semiconductor die being positioned within a gap of the verticalsurface of the first level downset lead extension to limit movement ofthe first leadless semiconductor die during stacking, wherein the firstleadless semiconductor die is a quad flat nonleaded package; and asecond leadless semiconductor die attached to the horizontal surface ofthe second level downset lead extension, the second leadlesssemiconductor die being positioned within a gap of the vertical surfaceof the second level downset lead extension to limit movement of thesecond leadless semiconductor die during stacking.
 7. The semiconductordevice of claim 6, further including an encapsulant formed over thefirst and second leadless semiconductor die for providing structuralsupport.
 8. The semiconductor device of claim 6, further including afirst wirebondable die attached to a first surface of the first leadlesssemiconductor die.
 9. The semiconductor device of claim 8, wherein thefirst wirebondable die is attached by an adhesive material.
 10. Thesemiconductor device of claim 9, wherein the adhesive material isconductive or non conductive.
 11. The semiconductor device of claim 6,wherein the second semiconductor die is a flip chip die.
 12. Asemiconductor device, comprising: a leadframe having a horizontalsurface and first and second level downset lead extensions, the firstlevel downset lead extension having a vertical surface extending fromthe horizontal surface of the leadframe, the first level downset leadextension further having a horizontal surface extending from thevertical surface of the first level downset lead extension, thehorizontal surface of the first level downset lead extension beingvertically offset from the horizontal surface of the leadframe, thesecond level downset lead extension having a vertical surface extendingfrom the horizontal surface of the first level downset lead extension,the second level downset lead extension further having a horizontalsurface extending from the vertical surface of the second level downsetlead extension, the horizontal surface of the second level downset leadextension being vertically offset from the horizontal surface of thefirst level downset lead extension; a first semiconductor die or packageattached to the horizontal surface of the first level downset leadextension, the first semiconductor die or package being positionedwithin a gap of the vertical surface of the first level downset leadextension to limit movement of the first semiconductor die or packageduring stacking, wherein the first semiconductor die or package is aquad flat nonleaded package; and a second semiconductor die or packageattached to the horizontal surface of the second level downset leadextension, the second semiconductor die or package being positionedwithin a gap of the vertical surface of the second level downset leadextension to limit movement of the second semiconductor die or packageduring stacking.
 13. The semiconductor device of claim 12, furtherincluding an encapsulant formed over the first and second semiconductordie or package for providing structural support.
 14. The semiconductordevice of claim 12, further including a third semiconductor die orpackage attached to a first surface of the first semiconductor die orpackage.
 15. The semiconductor device of claim 14, wherein the thirdsemiconductor die or package is attached by an adhesive material. 16.The semiconductor device of claim 15, wherein the adhesive material isconductive or non conductive.
 17. The semiconductor device of claim 12,wherein the second semiconductor die or package is a flip chip die.